Manufacturing costs for microsystems/MEMS using high aspect ratio microfabrication techniques

Lawes, Ron A.

doi:10.1007/s00542-006-0252-6

Cited by 46 publications

(32 citation statements)

References 11 publications

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“…UV-LIGA SU-8 was chosen as representative of photolithography since it is one of the most common techniques used [11]. A unit produced from the improved PAP method is defined as one microchannel while a unit produced for UV LIGA SU-8 is one wafer [11]. The cost per unit of a fabrication method was computed using the given equation:…”

Section: Cost Analysismentioning

confidence: 99%

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Low-Cost Fabrication of a PDMS Microchannel Using an Improved Print-and-Peel (PAP) Method

Yap¹,

Sanglay²,

Matuba³

et al. 2017

IJCEA

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Abstract-Microfluidics involves fluid dynamics, controlled fluid manipulations, and design of devices or systems in microchannels with typical dimensions of 10 to 200 micrometers. The conventional fabrication method of polydimethylsiloxane (PDMS) microchannels is soft lithography, which involves an expensive process for the preparation of master. The study aims to fabricate microchannels using print-and-peel (PAP) method for simple and low-cost construction of microfluidic systems. Based on the PAP method, a PDMS microchannel is developed using a master based on inkjet ink relief printed on paper. The study improves on the existing methodologies for PAP method by devising a technique called "printing-over", which is reprinting of the same pattern over itself at a high precision by modifying the printing process. This can produce irregularly-shaped molds with dimensions that can reach up to 200 micrometer width and 14.8 micrometer height, with aspect ratio equal to 0.07. Moreover, the aspect ratio is found to increase proportionally with number of printing-over runs. The microchannel produced from the mold has dimensions of 155 by 10 micrometers with aspect ratio of 0.06. With a rough cost analysis, the capital and variable costs of the PAP inkjet method are significantly lower than that of photolithography.Index Terms-Low-cost microfluidics, polydimethylsiloxane, print-and-peel method, inkjet printing. I. INTRODUCTIONMicrofluidics is the science that deals with the flow of liquids inside micrometer-size channels. This technology has found applications in various areas including biomedical engineering, cell biology, drug screening, chemical reaction engineering, and electrochemistry. While the main advantage of microfluidics is the reduction of costs by reducing fluid volumes, the conventional fabrication process requires specialized equipment in laboratories; and the material used, usually silicon chips, can be expensive to produce. Inducing controlled fluid flows in microfluidic channels is done using special equipment called microsyringe pumps, but these are also too expensive and are unavailable locally. The high costs associated with the fabrication of microfluidics consequently limits accessibility and thus, hinders its development especially in low-resource settings.The conventional fabrication method of polydimethylsiloxane (PDMS) microchannels is soft lithography, which involves an expensive process for the Manuscript received October 8, 2016; revised January 18, 2017. This work was supported in part by the UP Engineering Research and Development Foundation, Inc. (ERDFI) and the College of Engineering, University of the Philippines Diliman.The authors are with University of the Philippines Diliman, Quezon City 1101, Philippines (e-mail: kristian.yap@gmail.com). preparation of master called photolithography. Photolithography is a patterning process where light is used to transfer a pattern from a mask to a photosensitive polymer layer, and this resulting pattern can either be etched into the underlying su...

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Section: Cost Analysismentioning

confidence: 99%

“…A rough cost analysis was conducted based on the study in [11]. UV-LIGA SU-8 was chosen as representative of photolithography since it is one of the most common techniques used [11].…”

Section: Cost Analysismentioning

confidence: 99%

Low-Cost Fabrication of a PDMS Microchannel Using an Improved Print-and-Peel (PAP) Method

Yap¹,

Sanglay²,

Matuba³

et al. 2017

IJCEA

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“…Lost mold processes, such as injection molding of polymer molds (Knitter et al, 2001) and filling of photoresist molds (Schonholzer et al, 2000) offer the ability to create free standing parts large enough, with the desired edge resolution, to be viable options for microfabrication. Furthermore, mold fabrication via lithography is one of the least expensive microfabrication techniques (Lawes, 2007). New advances in ultra thick photoresist techniques permit the fabrication of single layer lithographic molds up to 1mm thick, while maintaining good edge resolution (Lin et al, 2002).…”

Section: Micro Scale Fabrication Techniquesmentioning

confidence: 99%

Fabrication of compliant mechanisms on the mesoscale

2011

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Abstract. The fabrication of compliant mechanisms on the mesoscale requires collaboration of mechanical engineering design, with materials science and engineering fabrication approaches. In this paper, a review of current fabrication approaches to produce mesoscale devices is given, highlighting the benefits and limitations of each technique. Additionally, a hierarchy is provided, eliminating fabrication techniques that do not completely satisfy the mechanical design requirements of the compliant mechanisms. Furthermore, the lost mold-rapid infiltration forming process (LM-RIF) is described, and compared to existing fabrication approaches. Finally, prototype mesoscale compliant mechanisms are fabricated, demonstrating the versatility of the LM-RIF process to produce both metal and ceramic devices, as well as ability of a fabrication process to work in collaboration with mechanical design.

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“…Packaging is widely recognized as a critical technological step because it is a limiting factor for performances, reliability and miniaturization of systems (Tummala 2001). In addition, when conventional packaging technologies are used, the main part of the production cost of packaged devices arises from the packaging step: its contribution was estimated to reach 50 to 90% for Micro Electro Mechanical Systems (MEMS) (Lawes 2007). Consequently, wafer level packaging (WLP), where all packaging functions are realized through wafer processing, is more and more considered as the best solution because it meets the demands of cost reduction, smaller package size and improved performances.…”

Section: Introductionmentioning

confidence: 99%

MEMS packaging process by film transfer using an anti-adhesive layer

et al. 2010

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A low cost and low temperature thin film packaging process based on the transfer of an electroplated Nickel 3D cap is proposed. This process is based on adhesion control of a thick molded cap Ni film on the carrier wafer by using a plasma deposited fluorocarbon film, on mechanical debonding and on adhesive bonding of the microcaps on the host wafer with BCB sealing rings. Mechanical characterizations show that the transferred microcaps have a high stiffness, a low stress and a high adhesion. Because this process is simple and only involves a low temperature (250°C) heating of the host wafer, it is highly versatile and suitable for the encapsulation of micro and nano devices, circuits and systems elaborated on a large range of substrate materials.

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Manufacturing costs for microsystems/MEMS using high aspect ratio microfabrication techniques

Cited by 46 publications

References 11 publications

Low-Cost Fabrication of a PDMS Microchannel Using an Improved Print-and-Peel (PAP) Method

Low-Cost Fabrication of a PDMS Microchannel Using an Improved Print-and-Peel (PAP) Method

Fabrication of compliant mechanisms on the mesoscale

MEMS packaging process by film transfer using an anti-adhesive layer

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